DE102007003586A1 - Automatic collimation device for a surveying device - Google Patents

Abstract

A surveying apparatus capable of performing automatic collimation even without angle detectors based on an image obtained by an imaging apparatus even with the telescope rotating is provided with: an imaging apparatus comprising a telescope-detected target (11) and the surroundings of the target (11); a drive unit (28, 30) rotating the telescope; a light emitting unit (24) which directs light toward the target (11); and an arithmetic control unit (32) which determines the position of the target (11) based on the difference between an illuminated image (a) obtained as a result of imaging by the imaging device with the light emitting unit (24) turned on and a non-illuminated image (b ) obtained as a result of imaging by the imaging device with the light emitting unit (24) turned off, and controlling the drive unit (28, 30) to automatically collimate the target (11), the arithmetic control unit (32) performing a correlation operation between the and the unlit image (b) to determine a position in which the images (a, b) have the largest coincidence and the position of the target (11) based on the difference between the two Images (a, b), determined at this position.

Description

The The present invention relates to an automatic collimation device for a Surveying equipment, an imaging device, such as a CCD area sensor, such that a destination based on one of the imaging device image obtained is automatically collimated.

Recently, a surveying apparatus which is constructed such that a target is automatically collimated based on an image obtained by the imaging apparatus is used. This type of surveying equipment is known from Japanese Patent 3621123 and in the 11 and 12 shown.

The well-known surveying device has, as in 11 shown, a telescope, consisting of an objective lens 1 , a dichroic mirror 2 , a condenser 3 and a solid state image capture device 4 on a collimation axis (optical axis) O. light, which is the objective lens 1 , the dichroic mirror 2 and the condenser 3 has passed to the solid state image capture device 4 focused.

In addition, the known surveying device has a light emitting unit 6 on, wherein from the light emitting unit 6 emitted modulated light along the Kollimationsachse O through a condenser 7 , a triangle mirror 5 , the dichroic mirror 2 and the objective lens 1 is directed. The modulated light transmitted along the collimating axis O returns due to the reflection by a target prism (hereinafter referred to a target) located at a measuring point along the collimation axis O, penetrates the objective lens 1 , the dichroic mirror 2 and the condenser 3 and finally falls on the solid state image capture device 4 , Part of the modulated light is from the dichroic mirror 2 and the triangle mirror 4 Reflects and falls through a condenser 9 to a light receiving unit 8th ,

In the known surveying apparatus, the phase difference between that of the light emitting unit 6 emitted modulated light and in the light receiving unit 8th incident modulated light is determined by a phase meter, not shown, and based on the phase difference, the distance to the target is calculated by an unillustrated arithmetic control unit. At this time, the horizontal angle and the vertical angle of the telescope (collimation axis) are measured by means of an unillustrated horizontal angle measuring unit (horizontal encoder) and a vertical angle measuring unit (vertical encoder).

During the Measuring the distance and the angle the target must be collimated so that it is positioned exactly on the collimation axis O. These Collimation is performed automatically as described below.

First, the telescope is on a target 11 directed and to a the goal 11 containing image according to 12 (A) to obtain a lit image in which the light emitting unit 6 Emits light and an unlit image with the light emitting unit switched off 6 by the solid state image capture device 4 won. By means of the arithmetic control unit, not shown, the difference between the two images is then determined. The difference between the two pictures becomes, as in 12 (B) shown, an image excluding the target 11 receive. This makes it possible to determine a horizontal deviation H and a vertical deviation V of the target 11 from the center of a raster indicating the direction of the collimation axis O. By turning the telescope by means of an unillustrated horizontal drive unit (horizontal servomotor) and a vertical drive unit (vertical servomotor) until the horizontal deviation H and the vertical deviation V are zero, the target can 11 automatically collimated.

Although the collimation described above is carried out with the telescope stationary, automatic collimation can also be performed with the telescope rotating. The angle of rotation of the telescope is determined by counting the output pulses of the horizontal angle measuring unit, not shown, and the vertical angle measuring unit. If, for example, a horizontally rotating surveying device, a difference in the telescopic angle between the period in which the light emitting unit 6 to receive a lighted image, and the period in which the light emitting unit emits light 6 is turned off to obtain a non-illuminated image, the shift amount X (angle difference) between the illuminated image and the non-illuminated image, as shown in FIG 12 (C) shown, can be easily calculated. When the shift amount X between the images is determined, the horizontal deviation H and the vertical deviation V can be easily calculated by determining the difference between both images by shifting either the illuminated image or the non-illuminated image by the shift amount X, and aim 11 can be collimated automatically.

Since the surveying apparatus known from Japanese Patent 3621123 is only able to perform automatic collimation using the angle detectors regardless of the fact that the telescope rotates or is silent, an automatic collimation at any time is only possible with angle detectors.

The above-described known surveying apparatus determines the shift amount X between that by the light of the light emitting unit 6 illuminated image and due to the switched off light emitting unit 6 unilluminated image using angle detectors, such as a horizontal encoder and a vertical encoder. However, some surveying equipment, such as leveling equipment, does not have angle detectors such as encoders. This in JP 3621123 described surveying device has the disadvantage that without angle detectors automatic collimation can not be performed with rotating telescope.

It It is the object of the present invention to provide a surveying device which is incorporated in capable of, based on an image obtained from an imaging device, perform an automatic collimation, so educate, that it is an automatic collimation without the use of angle detectors even with rotating telescope can perform.

The Task is according to the invention with the features of claim 1. Advantageous embodiments of the invention are specified in the subclaims.

at an automatic collimation device for a surveying device, comprising: an imaging device comprising a telescope The target and the surroundings of the target; a telescope turning Drive unit; a light emitting unit, the light in the direction of the destination; and an arithmetic control unit containing the Position of the target based on the difference between a lit one Picture as a result of the picture by the picture device is obtained when the light emitting unit is turned on, and a not lit image due to the picture by the imaging device is obtained when the light emitting unit is switched off, determined and the drive unit controls to automatically collimate the target is inventively provided that the arithmetic control unit performs a correlation operation between the lit image and the unlit image performs to determine a position in which the images have the greatest coincidence and the position of the target based on the difference determined between the two images at this coincidence position.

The The invention further contemplates that the position of greatest coincidence the pictures are considered to have been reached if during the course of a determination the correlation regarding overlapping each other Pixels of both images performed Correlation operation between the illuminated image and the unlit one Image the maximum correlation is reached.

The Invention further provides that the position of the largest coincidence of the images is considered to have been reached when in the course of a transversely performed correlation operation between the illuminated picture and the unlit picture, which serving in overlapping Regions of the two images, a correlation with respect to the total value of the brightness overlapping Pixels on a straight line in the longitudinal direction between the two To determine images, the maximum correlation is reached.

alternative the position of the largest coincidence holds according to the invention achieved as if in the course of a longitudinal direction performed correlation operation between the illuminated picture and the unlit picture, which serving in overlapping Regions of the two images, a correlation with respect to the total value of the brightness overlapping Pixels on a straight line in the transverse direction between both images to determine the maximum correlation is reached.

According to the invention the correlation operation is during moving either lit or unlit Picture performed, and the shiftable range at this time is one Area bounded by one of the arithmetic control unit estimated to be sent to the drive unit.

By the correlation between the illuminated and the non-illuminated Image and determining the position of the largest coincidence of both images and determining the position of a target based on the difference between the pictures at the coincidence position it is possible without Angle detectors automatically collimate even when rotating Perform telescope. Further, the position of the largest coincidence is reached when the maximum correlation between overlapping Areas of images is reached, the position of the largest coincidence the pictures easily and reliably determinable.

through a directional and determined by the total brightness value Correlation of the two images can, as previously described, the Positions of greatest coincidence both in the transverse direction, as well as in the longitudinal direction with less computational effort as determined in the aforementioned non-directional correlation, which makes the automatic collimation faster can.

Since the correlation operation during the If one of the two images is shifted and the respective shift range is limited to an estimated range based on a control signal, the time required to determine the correlation between the two images is shortened and the position of the largest coincidence of the two images can be used for the accelerated execution of the automatic Collimation be determined.

The Invention will be described below with reference to exemplary embodiments with reference on the associated Drawings closer described. Show it:

1 a block diagram of an automatic collimation device for a surveying device according to a first embodiment of the invention;

2 a diagram for explaining an optical system of the automatic collimation device;

3 a plan view of a surface sensor used in the automatic collimation;

4 an optical system in which the automatic collimation device is integrated into a total station;

5 Illustrations for explaining principles of the automatic collimation device;

6 a diagram for explaining a correlation;

7 Representations for explaining a method for determining a range by which an illuminated and a non-illuminated image are shifted in an operation for correlation of both images;

8th Representations for explaining principles of an automatic correlation device for a surveying device according to a second embodiment of the invention;

9 an optical system in which an automatic collimation device according to a third embodiment of the invention is integrated into an automatic leveling device;

10 an optical system in which an automatic collimation device according to a third embodiment of the invention is integrated in an electronic leveling device;

11 a diagram for explaining an optical system of a conventional surveying device with an imaging device;

12 Illustrations illustrating the principles of an automatic collimation device for a conventional surveying device with an imaging device.

First, based on the 1 to 7 a first inventive embodiment of an automatic collimation for a surveying device described.

As in 1 illustrated, the inventive automatic collimation device comprises: a light emitting unit 24 , which emits collimating light, an area sensor 20 For example, a CCD that represents an imaging device that receives the collimated light reflected from a target, an image processor 21 that of the area sensor 20 get ne processed image, and a horizontal drive unit 28 and a vertical drive unit 30 rotating a telescope using a microcomputer (arithmetic control unit) 32 are connected. The microcomputer 32 controls the horizontal drive unit 28 and the vertical drive unit 30 based on one of the image processor 21 processed target image to the target in exact accordance with the origin of the coordinates of the area sensor 20 bring to. The microcomputer 32 is further provided with a display unit 22 connected, and a measured value, one of the area sensor 20 The image obtained and the like are displayed on the display unit 22 displayed.

According to 2 The telescope (collimating optical system) of the surveying device consists of an objective lens 41 , a focusing lens 43 , a reverse prism 44 , a reticule glass 47 and an eyepiece lens 48 which are arranged on a Kollimationsachse (optical axis) O. The optical system of the automatic collimation device 40 consists of the light emitting unit 24 which emits collimating light, a collimator lens 26 which collimates the collimating light into parallel light beams, a reflecting mirror 45 and a reflective prism 46 that the collimating light is perpendicular to the objective lens 41 , a dichroic mirror 42 and the area sensor 20 reflect.

Because of the objective lens 41 condensed natural light through the dichroic prism 42 penetrates, the target image is on the reticle glass 47 focused. The user can view the target image through the eyepiece lens 48 and then make a manual collimation. On the other hand happens from the light emitting unit 24 emitted collimating light the collimator lens 26 , where the light path is perpendicular to the reflective mirror 45 and the reflective prism 46 deflected and then directed along a Kollimationsachse O. The directional collimating light returns due to the reflection by a target along the collimation axis O, becomes from the objective lens 41 condensed, through the dichroic prism 42 reflected at right angles and falls on the surface sensor 20 ,

The area sensor 20 is how in 3 represented by arranging pixels 50 in a grid pattern, and by determining a line i on a transverse straight line I and a column j on a longitudinal straight line J, so that those of each one of the pixels 50 received amount of light, ie the brightness, to the microcomputer 32 can be issued. That of the area sensor 20 obtained image, which includes the target and a background, can via the microcomputer 32 on the display unit 22 are displayed.

4 is an example of an optical system in which the automatic collimation device 40 integrated into a total station. In addition to the optical system of the automatic collimation device 40 and the above-described optical system of the telescope is provided in a total station, an optical system of an electric rangefinder. The optical system of the electric rangefinder consists of a light emitting unit 60 for measuring the distance, a beam splitter 62 , a dichroic prism 64 , the objective lens 41 a light receiving element 66 and a reference light path 68 of the light emitted from the light emitting unit for the distance measurement 60 for distance measurement directly to the light receiving element 66 passes. Although the collimating axes O of these optical systems are all formed as an identical axis, the electric rangefinder may be separate from the automatic collimating device and the collimating optical system, and the collimating axes thereof may be provided in parallel above and below. Since the electric rangefinder in the present case is similar to those of the prior art, no detailed description will be given here.

In the automatic collimation device 40 apply at standstill telescope the same principles as in the known device according to Japanese Patent 3621123, ie, the microcomputer 32 Detects a target position and performs an automatic collimation. Based on 5 be for the automatic collimation device 40 in the following Erken NEN of the target position by the microcomputer 32 and performing automatic collimation while rotating the telescope.

First, in light-emitting light emitting unit 24 a lit picture a (see 5 (A) ) and with the light emitting unit switched off 24 a non-illuminated image b (see 5 (B) ) from the imaging device 20 receive. Since the surveying device is rotating, there is an offset between the images a and b. During a gradual shift of one of the two images a and b, as in the 5 (C) is shown with respect to the respective brightness An and Bn (where n is the number of pixels) of the overlapping pixels 50 the two images a and b in a correlation operation determines a correlation. If the brightnesses An and Bn are plotted along the longitudinal or the transverse axis, the correlation diagram according to FIG 6 , As can be seen from the correlation diagram, the concentration of the points indicating the brightnesses An and Bn is in the vicinity of a right-rising line 52 larger with increasing correlation. The correlation is maximal when both images a and b coincide, as in 5 (D) shown.

To automatically determine the correlation, a correlation coefficient is used. For both images a and b, where the average brightness of the overlapping pixels 50 the two images a and b are given Am and Bm, the standard deviations of the overlapping pixels 50 both images a and b are labeled As and Bs, and the total number of overlapping pixels 50 of the two images a and b is given N, a correlation coefficient r is determined by means of the following expression. r = Σ {(An-Am) (Bn-Bm)} / N ö (As · Bs)

In 5 (C) one of the two pictures a and b is only moved in one direction (here in the transverse direction). In fact, however, after a position in which the correlation coefficient between the images a and b is maximum is determined by shifting one of the two images in the longitudinal or transverse direction, by shifting one of the two images a and b also in the other direction determines a position in which the correlation coefficient between the images a and b is also maximum.

If the correlation coefficient between the two images has been maximized in this way, by determining the difference between the two images a and b at that position, the target can 11 be extracted alone, as in 5 (E) shown. Thereafter, as in the aforementioned known device, the horizontal deviation H and the vertical deviation V from the center of the display unit 22 , which determines the direction of the collimation axis O, determines and the target 11 can be collimated automatically.

However, for determining the position of the maximum correlation coefficient, it is not necessary to determine the correlation coefficient over a range from a point where both images a and b completely overlap to a complete non-overlap of the images. Because the (by the number of pixels of the area sensor 20 specified) speeds of the respective servomotors of the horizontal drive unit 28 and the vertical drive unit 30 a control signal of the microcomputer 32 are adapted, the shift amount between the two images a and b from the time difference T between the obtaining of the exposed image a, by emitting light from the light emitting unit 24 was generated, and the light emitting unit is switched off 24 obtained image b and speed setpoints of the servomotors are estimated. It is therefore sufficient to determine the correlation coefficient between both images a and b while shifting one of them within a limited range, the amount of shift between the two images a and b being estimated.

When the speed command values of the servomotors are increased from 0 (stop) to a maximum positive speed + Vf, the shift amount X at the maximum correlation coefficient between both images a and b is between 0 and + Vf · T. As in 7 (A) Therefore, it is sufficient, while shifting one of the two images a and b in the lateral and longitudinal directions, to determine the correlation coefficient in a limited range, with the shift amount X between the images being between 0 and + Vm * T.

When the speed command values of the servomotors range from a mean negative speed -Vm to 0 (stop), the shift amount X at the maximum correlation coefficient between the images a and b is between -Vm * T and 0. As shown in FIG 7 (B) Therefore, it is sufficient to determine the correlation coefficient in a limited range while shifting one of the two images a and b in both the lateral and longitudinal directions, with the shift amount X between the images being between -Vf * T and 0.

If the speed command values of the servomotors range from the maximum positive speed + Vf to the average negative speed -Vm, the shift amount X at the maximum correlation coefficient between the images a and b is between -Vm * T and + Vf * T. As in 7 (C) Therefore, while shifting one of the two images a and b in both the lateral and longitudinal directions, it is sufficient to determine the correlation coefficient in a limited range, the shift amount X between the images being between -Vm * T and + Vf * T lies.

When the speed command values of the servomotors are complicatedly changed in a certain period of time, and the maximum speed and the minimum speed during this period are + Vf and Vs, respectively, the shift amount X at maximum correlation coefficient between the images a and b is + Vs. T and + Vf · T. As in 7 (D) Therefore, while shifting one of the two images a and b in both the lateral and longitudinal directions, it is sufficient to determine the correlation coefficient in a limited range, the shift amount X between the images being between + Vs * T and + Vf * T lies.

As described above, in the automatic collimation apparatus of the present invention 40 Even with surveying instruments without angle detectors, such as angle encoders, it is not necessary to determine the rotation angle of the telescope when both images a and b are obtained, it is by providing the automatic collimation device 40 possible to perform an automatic collimation even when the telescope is rotating. Further, since the correlation coefficient is determined in a limited range, the shift amount X between both images a and b is estimated, the position of the maximum correlation coefficient can be determined within a short time, so that fast automatic collimation is also possible.

Based on 8th In the following, a second embodiment of the invention will be described. 8th 11 shows views for explaining the principles of the automatic collimation device according to the present invention. The automatic collimating apparatus has the same structure as the surveying apparatus according to the first embodiment, and the process until obtaining a light emitting unit emitting light 24 illuminated picture a (s. 8 (A) ) and one with the light emitting unit switched off 24 obtained unilluminated image b, respectively, by means of the imaging device 20 are obtained, corresponds to the procedure described in connection with the first embodiment. However, as described below, the second embodiment differs from the first embodiment in the method of the correlation operation for determining a position in which the largest coincidence of both images a and b exists.

After both pictures a and b as in the 8 (A) and 8 (B) are obtained, in overlapping regions of the two images a and b, respectively, the totals Ax and Bx of the brightness of all pixels with respect to each column j along a straight line J in the longitudinal direction and the totals Ay and By of the brightness of all the Pi xel with respect to each line i along a straight line I determined in the transverse direction.

Subsequently, as in 8 (C) 4, during the stepwise shifting of one of the two images a and b in the transverse direction, a correlation coefficient with respect to the total sums Ax and Bx of the brightness of each overlapping column j of the two images a and b is determined. When the correlation coefficient of the total sums Ax and Bx of the brightness is maximum, the largest coincidence of the two images a and b in the transverse direction is considered to be achieved.

After that, as in 8 (D) 4, during the stepwise shifting of one of the images a and b in the longitudinal direction, a correlation coefficient with respect to the total sums Ay and By of the brightness of each overlapping line i between both images a and b is determined. When the correlation coefficient of the total sums Ay and By of the brightness is maximum, the maximum coincidence of the two images a and b in the longitudinal direction is considered to be reached. Subsequently, the goal can be 11 automatically collimated as in the first embodiment.

Since the correlation coefficients for the totals of the brightness of the pixels 50 each line i and each column j have been determined, in the second embodiment, a point where the largest coincidence of the two images a and b exists can be determined with a lower computational effort than in the first embodiment in which the correlation coefficient with respect to all pixels 50 is determined. Therefore, the automatic collimation can be performed faster.

In the following, an automatic collimation device of a surveying apparatus according to a third embodiment of the invention will be described. 9 Fig. 10 is a diagram for explaining an optical system in which the automatic collimation device is integrated with an automatic leveling device. 10 Fig. 12 is a diagram for explaining an optical system in which the automatic collimation device is integrated with an electronic leveling device.

When the automatic collimation device 40A , as in 9 In addition, an automatic horizontal compensation mechanism is shown integrated in an automatic leveling device 49 provided, which compensates for the flatness of the Kollimationsachse O. However, since it is not necessary to turn the telescope up and down, eliminates the vertical drive unit 30 , The other components are the same as those of the automatic collimation device 40 of the 2 , This makes it possible to automatically collimate a leveling rod while simultaneously compensating the flatness of the collimation axis O, even when the telescope is rotating, without requiring either horizontal or vertical encoders.

When the automatic collimation device 40A in an electronic leveling device according to 10 are integrated, in comparison with the components according to 9 one with the microcomputer 32 connected line sensor 70 and a dichroic prism 72 , which light along the Kollimationsachse O in the direction of the line sensor 70 reflected, additionally provided. The remaining components are the same as those shown in FIG 9 , This enables the automatic collimating of a leveling rod while compensating for the flatness of the collimation axis O, and further enables focusing an image of the rod arranged at a survey point on the line sensor 70 and reading a scale of the rod by the microcomputer 32 ,

The third embodiment of the automatic collimation device 40A As before, there are no angle detectors, such as encoders, but with the automatic horizontal compensation mechanism 49 and is used exclusively for an automatic or electronic leveling device, in which the telescope does not have to be turned up and down. Similar to the embodiments described above is also the automatic collimation 40A according to the third embodiment, capable of performing automatic collimation even when the telescope rotates.

The However, the present invention is not limited to the described embodiments limited and can be modified in different ways. In the previously described embodiments was used in the correlation operation to determine the point of largest coincidence of the images a and b this point by means of the correlation coefficient between the two pictures a and b determined, however, this can Point can be determined by any other suitable method.

For example, the position of the largest coincidence of both images a and b can be determined based on a position where the ratio of the respective brightness An and Bn of the overlapping pixels 50 indicating points in the region C of the correlation diagram of FIG 6 is maximum. Moreover, a residual correlation method may be used to determine the residual correlation based on a position where the sum of squares of a difference between the brightnesses An and Bn has the lowest value. Further, a phase-only correlation method (Fourier phase correlation method) may be used to determine the same from a position at which, as a result of frequency analysis, the brightnesses of At and Bn the degree of similarity in a phase part is maximum.

11

aim

20

area sensor

25

light emitting unit

28

Horizontal drive unit (Drive unit)

30

Vertical drive unit (Drive unit)

32

microcomputer (arithmetic control unit)

40 40A

automatic collimation

50

pixel

a

illuminated image

b

Not illuminated picture

Claims (5)

Automatic collimating device for a surveying apparatus, comprising: an imaging device that detects a target detected by a telescope ( 11 ) and the surroundings of the destination ( 11 ) maps; a drive unit rotating the telescope ( 28 . 30 ); a light emitting unit ( 24 ), the light in the direction of the target ( 11 ); and an arithmetic control unit ( 32 ) showing the position of the target ( 11 ) based on the difference between a lighted image (a), due to the imaging by the imaging device with light emitting unit ( 24 ) and a non-illuminated image (b), which, as a result of the imaging by the imaging device with the light emitting unit switched off ( 24 ) and the drive unit ( 28 . 30 ) controls the target ( 11 ) to collimate automatically, characterized in that the arithmetic control unit ( 32 ) performs a correlation operation between the illuminated image (a) and the unlit image (b) to determine a position in which the images (a, b) have the largest coincidence, and the position of the target (a) 11 ) determined based on the difference between the two images (a, b) at this position. Automatic collimation device for a surveying device according to claim 1, characterized in that the position of the greatest coincidence of the images (a, b) is considered to have been reached during the course of determining a correlation with respect to overlapping pixels ( 50 ) of both images (a, b) between the illuminated image (a) and the unlit image (b) the maximum correlation is achieved. Automatic collimation device for a surveying device according to claim 1, characterized in that the position of maximum coincidence of the images (a, b) is considered to have been reached when, during a transverse correlation operation between the illuminated image (a) and the unlit image (b ), which serves in overlapping regions of the two images (a, b) to correlate with respect to the total value of the brightness of overlapping pixels (FIG. 50 ) on a straight line longitudinally between both images (a, b) to determine the maximum correlation is reached. Automatic collimating apparatus for a surveying apparatus according to claim 1, characterized in that the position of the maximum coincidence of the images (a, b) is considered to have been reached during the course of a longitudinal correlation operation between the illuminated image (a) and the unlit image (b ), which serves in overlapping regions of the two images (a, b) to correlate with respect to the total value of the brightness of overlapping pixels (FIG. 50 ) on a straight line in the transverse direction between both images (a, b) to determine the maximum correlation is reached. Automatic collimating apparatus for a surveying apparatus according to any one of claims 1 to 4, characterized in that the correlation operation is performed during shifting of either the illuminated (a) or unlit image (b), and the area displaceable at that time is limited to one area determined by one of the arithmetic control unit ( 32 ) to the drive unit ( 28 . 30 ) is estimated.